Dielectric-Relaxation Spectroscopy of Kaolinite, Montmorillonite, Allophane, and Imogolite under Moist Conditions

The dielectric behavior of kaolinite, montmorillonite, allophane, and imogolite samples adjusted to a water potential of 33 kPa was examined using a time-domain reflectometry method over a wide frequency range of 103-1010 Hz. A dielectric relaxation peak owing to bound H2O was observed. The observation of this peak required the precise determination of the contributions of dc conductivity. The peak is located at 10 MHz, indicating that the relaxation time of the bound H2O is approximately ten times longer than the relaxation time of bound H2O with organic polymers, such as an aqueous globular-protein solution. The structure of bound H2O differs between phyllosilicates and amorphous phases, based on differences in relaxation strength and the pattern of distribution of the relaxation times. The dielectric process involving rotation of bulk H2O molecules was also observed at 20 GHz. The relaxation strength of bulk H2O increased with an increase in the water content. The interfacial polarization in the diffuse double layer occurred only in montmorillonite and kaolinite, indicating that mechanisms involving the Maxwell-Wagner and surface-polarization effects cannot be extended to include allophane and imogolite. Although these results suggest that additional work is required, a tentative conclusion is that a tangential migration of counter-ions along clay surfaces may be important.

[1]  Teruo Henmi Idea and Methodology on the Study of Amorphous Clays , 1991 .

[2]  P. N. Sen,et al.  Relation of certain geometrical features to the dielectric anomaly of rocks , 1981 .

[3]  R. Kimmich,et al.  Nuclear Magnetic Relaxation Spectroscopy in Solutions of Bovine Hemoglobin , 1971, Zeitschrift fur Naturforschung. Teil B, Chemie, Biochemie, Biophysik, Biologie und verwandte Gebiete.

[4]  N. Sasaki,et al.  Microwave dielectric study on hydration of moist collagen , 1990, Biopolymers.

[5]  M. L. Jackson,et al.  Iron oxide removal from soils and clays by a dithionite-citrate system buffered with sodium bicarbonate. , 1960 .

[6]  R. Cole,et al.  Evaluation of dielectric behavior by time domain spectroscopy. II. Complex permittivity , 1975 .

[7]  N. Shinyashiki,et al.  Evaluation of complex permittivity of aqueous solution by time domain reflectometry , 1987 .

[8]  G. Schwarz A THEORY OF THE LOW-FREQUENCY DIELECTRIC DISPERSION OF COLLOIDAL PARTICLES IN ELECTROLYTE SOLUTION1,2 , 1962 .

[9]  N. C. Lockhart,et al.  Electrical properties and the surface characteristics and structure of clays. II. Kaolinite—a nonswelling clay , 1980 .

[10]  Shin Yagihara,et al.  Dielectric relaxation time and structure of bound water in biological materials , 1987 .

[11]  Naoki Shinyashiki,et al.  Microwave dielectric study on bound water of globule proteins in aqueous solution , 1994 .

[12]  J. André,et al.  Thermodynamic Properties of Adsorbed Water Molecules and Electrical Conduction in Montmorillonites and Silicas , 1965 .

[13]  N. Yoshinaga Chemical composition and some thermal data of eighteen allophanes from ando soils and weathered pumices , 1966 .

[14]  N. E. Hill,et al.  Dielectric properties and molecular behaviour , 1969 .

[15]  P. Sen,et al.  Dielectric properties of clay suspensions in MHz to GHz range , 1986 .

[16]  R. Cole,et al.  Evaluation of dielectric behavior by time domain spectroscopy. 3. Precision difference methods , 1980 .

[17]  O. P. Mehra,et al.  Iron Oxide Removal from Soils and Clays by a Dithionite-Citrate System Buffered with Sodium Bicarbonate , 1958 .

[18]  S. Havriliak,et al.  A complex plane representation of dielectric and mechanical relaxation processes in some polymers , 1967 .

[19]  M. Haida,et al.  Comparison of Water Relaxation Time in Serum Albumin Solution Using Nuclear Magnetic Resonance and Time Domain Reflectometry , 1995 .

[20]  M. Jackson Soil Chemical Analysis - Advanced Course. , 1969 .

[21]  R. Cole,et al.  Dielectric properties of electrolyte solutions. 2. Alkali halides in methanol , 1982 .

[22]  Makino,et al.  Effects of pH on Dielectric Relaxation of Montmorillonite, Allophane, and Imogolite Suspensions. , 1999, Journal of colloid and interface science.

[23]  R. W. Sillars The properties of a dielectric containing semiconducting particles of various shapes , 1937 .

[24]  Pieter Hoekstra,et al.  Dielectric relaxation of surface adsorbed water , 1971 .

[25]  N. C. Lockhart Electrical properties and the surface characteristics and structure of clays. I. Swelling clays , 1980 .

[26]  B. Goldsmith,et al.  Surface ion effects in the dielectric properties of adsorbed water films , 1960 .

[27]  R. Cole,et al.  Dielectric properties of electrolyte solutions. 1. Sodium iodide in seven solvents at various temperatures , 1982 .

[28]  J. Chaussidon,et al.  Surface Conductivity and Dielectrical Properties of Montmorillonite Gels , 1968 .

[29]  Garrison Sposito,et al.  Structure of water adsorbed on smectites , 1982 .

[30]  Makino,et al.  Microwave Dielectric Relaxation of Bound Water to Silica, Alumina, and Silica-Alumina Gel Suspensions. , 1999, Journal of colloid and interface science.

[31]  S. Dukhin,et al.  Non-equilibrium electric surface phenomena , 1993 .

[32]  G. Sposito Single‐particle motions in liquid water. II. The hydrodynamic model , 1981 .

[33]  S. Iwata,et al.  Differential heat of water adsorption for montmorillonite, kaolinite and allophane , 1989, Clay Minerals.

[34]  Mark A. Rose,et al.  Dielectric properties of water adsorbed by kaolinite clays , 1978 .

[35]  S. Yagihara,et al.  Dielectric study on dynamics and structure of water bound to DNA using a frequency range 107-1010 Hz , 1989 .

[36]  S. Yagihara,et al.  Dielectric study on hydration of B‐, A‐, and Z‐DNA , 1990, Biopolymers.

[37]  R. Cole Evaluation of dielectric behavior by time domain spectroscopy. I. Dielectric response by real time analysis , 1975 .

[38]  R. Calvet,et al.  Dielectric Properties of Montmorillonites Saturated by Bivalent Cations , 1975 .